System and method for determining a position for a scleral pocket for a scleral prosthesis

ABSTRACT

For use with a surgical tool for making incisions in the sclera of an eye to form a scleral pocket to receive a scleral prosthesis, a system and method is disclosed for determining a position on the sclera for locating the scleral pocket. The system and method determines an optimum location for the scleral pocket. The system and method determines a location on the sclera that represents the intersection of the lens equatorial plane with the external surface of the sclera. The front of the scleral pocket is placed at a location that is four hundred fifty microns posterior to the intersection of the lens equatorial plane with the external surface of the sclera.

PRIORITY CLAIM TO PRIOR PATENT APPLICATIONS

This application is a continuation of prior U.S. patent application Ser. No. 10/443,122 filed May 20, 2003, now U.S. Pat. No. 7,909,780, which claims benefit of U.S. Provisional Patent Application Ser. No. 60/381,851 filed May 20, 2002, and is a continuation-in-part of U.S. patent application Ser. No. 10/080,877 filed Feb. 22, 2002 now U.S. Pat. No. 7,189,248 and a continuation-in-part of U.S. patent application Ser. No. 10/080,986 filed Feb. 22, 2002, now U.S. Pat. No. 6,926,727.

CROSS-REFERENCE TO RELATED PATENT DOCUMENTS

The present disclosure is related to the inventions disclosed in the following United States patent applications and issued United States patents:

-   -   (1) U.S. Pat. No. 6,299,640 entitled “SCLERAL PROSTHESIS FOR         TREATMENT OF PRESBYOPIA AND OTHER EYE DISORDERS” issued on Oct.         9, 2001;     -   (2) U.S. Pat. No. 6,197,056 entitled “SEGMENTED SCLERAL BAND FOR         TREATMENT OF PRESBYOPIA AND OTHER EYE DISORDERS” issued on Mar.         6, 2001;     -   (3) U.S. Pat. No. 6,280,468 entitled “SCLERAL PROSTHESIS FOR         TREATMENT OF PRESBYOPIA AND OTHER EYE DISORDERS” issued Aug. 28,         2001;     -   (4) U.S. Pat. No. 5,465,737 entitled “TREATMENT OF PRESBYOPIA         AND OTHER EYE DISORDERS” issued on Nov. 14, 1995;     -   (5) U.S. Pat. No. 5,489,299 entitled “TREATMENT OF PRESBYOPIA         AND OTHER EYE DISORDERS” issued on Feb. 6, 1996;     -   (6) U.S. Pat. No. 5,503,165 entitled “TREATMENT OF PRESBYOPIA         AND OTHER EYE DISORDERS” issued on Apr. 2, 1996;     -   (7) U.S. Pat. No. 5,529,076 entitled “TREATMENT OF PRESBYOPIA         AND OTHER EYE DISORDERS” issued on Jun. 25, 1996;     -   (8) U.S. Pat. No. 5,354,331 entitled “TREATMENT OF PRESBYOPIA         AND OTHER EYE DISORDERS” issued on Oct. 11, 1994; and     -   (9) U.S. Pat. No. 5,722,952 entitled “TREATMENT OF PRESBYOPIA         AND OTHER EYE DISORDERS” issued on Mar. 3, 1998;     -   (10) U.S. patent application Ser. No. 10/080,877 entitled         “SYSTEM AND METHOD FOR MAKING INCISIONS FOR SCLERAL EYE         IMPLANTS” filed on Feb. 22, 2002; and     -   (11) U.S. patent application Ser. No. 10/080,986 entitled         “SURGICAL BLADE FOR USE WITH A SURGICAL TOOL FOR MAKING         INCISIONS FOR SCLERAL EYE IMPLANTS” filed on Feb. 22, 2002 which         are commonly owned by the assignee of the present invention. The         disclosures of these related United States patent applications         and issued United States patents (collectively referred to         hereafter as the “Presbyopia and Related Eye Disorder Patent         Documents”) are incorporated herein by reference for all         purposes as if fully set forth herein.

FIELD OF THE INVENTION

The present invention relates generally to the treatment of presbyopia, hyperopia, primary open angle glaucoma, ocular hypertension and other similar eye disorders. The present invention comprises a system and method for determining a position for making an incision in the sclera of an eye to form a scleral pocket for the eye to receive a scleral prosthesis. Scleral prostheses are capable of increasing the amplitude of accommodation of the eye by increasing the effective working distance or range of the ciliary muscle of the eye.

BACKGROUND OF THE INVENTION

In order for the human eye to have clear vision of objects at different distances, the effective focal length of the eye must be adjusted to keep the image of the object focused as sharply as possible on the retina. This change in effective focal length is known as accommodation and is accomplished in the eye by varying the shape of the crystalline lens. Generally, in the unaccommodated emmetropic eye the curvature of the lens is such that distant objects are sharply imaged on the retina. In the unaccommodated eye near objects are not focused sharply on the retina because their images lie behind the retinal surface. In order to visualize a near object clearly, the curvature of the crystalline lens is increased, thereby increasing its refractive power and causing the image of the near object to fall on the retina.

The change in shape of the crystalline lens is accomplished by the action of certain muscles and structures within the eyeball or globe of the eye. The lens is located in the forward part of the eye, immediately behind the pupil. It has the shape of a classical biconvex optical lens, i.e., it has a generally circular cross section having two convex refracting surfaces, and is located generally on the optical axis of the eye, i.e., a straight line drawn from the center of the cornea to the macula in the retina at the posterior portion of the globe. In the unaccommodated human eye the curvature of the posterior surface of the lens, i.e., the surface adjacent to the vitreous body, is somewhat greater than that of the anterior surface. The lens is closely surrounded by a membranous capsule that serves as an intermediate structure in the support and actuation of the lens. The lens and its capsule are suspended on the optical axis behind the pupil by a circular assembly of very many radially directed elastic fibers, the zonules, which are attached at their inner ends to the lens capsule and at their outer ends to the ciliary body and indirectly to the ciliary muscle, a muscular ring of tissue, located just within the outer supporting structure of the eye, the sclera. The ciliary muscle is relaxed in the unaccommodated eye and therefore assumes its largest diameter. According to the classical theory of accommodation, originating with Helmholtz, the relatively large diameter of the ciliary muscle in this condition causes a tension on the zonules which in turn pulls radially outward on the lens capsule, causing the equatorial diameter of the lens to increase slightly and decreasing the anterior-posterior dimension of the lens at the optical axis. Thus, the tension on the lens capsule causes the lens to assume a flattened state wherein the curvature of the anterior surface, and to some extent the posterior surface, is less than it would be in the absence of the tension. In this state the refractive power of the lens is relatively low and the eye is focused for clear vision for distant objects.

When the eye is intended to be focused on a near object, the ciliary muscles contract. According to the classical theory, this contraction causes the ciliary muscle to move forward and inward, thereby relaxing the outward pull of the zonules on the equator of the lens capsule. This reduced zonular tension allows the elastic capsule of the lens to contract causing an increase in the antero-posterior diameter of the lens (i.e., the lens becomes more spherical) resulting in an increase in the optical power of the lens. Because of topographical differences in the thickness of the lens capsule, the central anterior radius of curvature decreases more than the central posterior radius of curvature. This is the accommodated condition of the eye wherein the image of near objects falls sharply on the retina.

Presbyopia is the universal decrease in the amplitude of accommodation that is typically observed in individuals over forty years of age. In the person having normal vision, i.e., having emmetropic eyes, the ability to focus on near objects is gradually lost, and the individual comes to need glasses for tasks requiring near vision, such as reading.

According to the conventional view the amplitude of accommodation of the aging eye is decreased because of the loss of elasticity of the lens capsule and/or sclerosis of the lens with age. Consequently, even though the radial tension on the zonules is relaxed by contraction of the ciliary muscles, the lens does not assume a greater curvature. According to the conventional view, it is not possible by any treatment to restore the accommodative power to the presbyopic eye. The loss of elasticity of the lens and capsule is seen as irreversible, and the only solution to the problems presented by presbyopia is to use corrective lenses for close work, or bifocal lenses, if corrective lenses are also required for distant vision.

Contrary to the conventional view, it is possible to restore the accommodative power to a presbyopic eye by implanting a plurality of scleral prostheses within the sclera of the eye. For each individual scleral prosthesis an incision is made in the sclera of the globe of the eye near the plane of the equator of the crystalline lens. The incision is then extended under the surface of the sclera to form a scleral “pocket.” The scleral prosthesis is then placed within the pocket. A typical scleral prosthesis comprises a generally rectangularly shaped bar approximately five millimeters (5.0 mm) long, one and one half millimeters (1.5 mm) wide, and one millimeter (1.0 mm) tall. The anterior edge of the scleral prosthesis applies an outward force on the anterior edge of the scleral pocket which elevates the anterior portion of the sclera attached thereto and the ciliary body immediately beneath the sclera to increase the working distance of the ciliary muscle. This method is described more fully in the “Presbyopia and Related Eye Disorder Patent Documents” that have been incorporated by reference into this patent document.

A physician who makes the incisions to form a scleral pocket must be a very skilled surgeon. The surgeon must use great care to ensure that the incisions are made properly. The incisions that must be made to form a scleral pocket are quite small. The incisions must be made at precisely the correct depth. The width and length of the scleral pocket must also be formed by very precise incisions.

It is well known that physicians may differ significantly with respect to the level of surgical skill that they possess. Physicians who practice surgery regularly generally become quite skilled. Other physicians who do not practice surgery regularly are less skilled. Even skilled surgeons may find it difficult to make the precise incisions that are required to correctly form a scleral pocket.

If scleral pocket incisions are not made with sufficient precision the resulting scleral pocket will not be able to correctly support a scleral prosthesis. An incorrectly supported scleral prosthesis is not able to provide an acceptable level of vision correction.

A scleral pocket must be located on the sclera with sufficient precision to ensure that a scleral prosthesis that is placed within the scleral pocket will be able to function correctly. An incorrectly located scleral pocket will not enable a scleral prosthesis to provide an acceptable level of vision correction.

It would be desirable if a system and method existed that would allow a surgeon to precisely locate an optimal position for forming a scleral pocket within the sclera of an eye. Accordingly, a need exists in the art for a system and method that is capable of precisely locating a position on the sclera of an eye to form a scleral pocket to receive a scleral prosthesis.

SUMMARY OF THE INVENTION

The present invention comprises a system and method that is capable of determining an optimal location on the sclera of an eye to form a scleral pocket to receive a scleral prosthesis.

The surgical tool for use with the system and method of the present invention comprises a base housing and a drive shaft housing. The base housing of the surgical tool receives electrical power and control signals from an external surgical tool controller. The drive shaft housing comprises a blade mount housing that is mounted on the drive shaft housing at an angle to a central axis of the drive shaft housing. A rotatable blade for making incisions in the sclera of an eye is mounted on the blade mount housing.

A surgeon positions the rotatable blade of the surgical tool over the sclera of an eye. The surgeon determines the location of the scleral pocket by using information that is provided by the system and method of the present invention. The surgeon then places the blade mount housing on the sclera of the eye. A pressure sensor determines when there is sufficient pressure between the surgical tool and the sclera of the eye for the surgical tool to operate properly. When the pressure sensor detects sufficient pressure the surgical tool may be activated. The surgeon sends an activation signal to the surgical tool to cause the rotatable blade to advance through the sclera to form an incision having dimensions to receive a scleral prosthesis. The sclera of the eye and the surgical tool are restrained from moving while the rotatable blade is rotated through the sclera to make an incision. When the incision is complete the rotatable blade is rotated back out of the incision. The incision then has the exact dimensions to receive a scleral prosthesis.

The apparatus of the present invention comprises a controller that is capable, among other functions, of receiving eye measurements that measure characteristics of the eye, such as a size of portions of an eye. The controller comprises a software processor and an eye model application software program within the software processor. The eye model application software program uses the eye measurements to create a mathematical model of the eye. The controller determines from the mathematical model of the eye a location on the sclera of the eye that is the optimum location for a scleral pocket to receive a scleral prosthesis.

It is an object of the invention to provide scleral pocket location information to a surgeon who is operating a surgical tool that is capable of making precise incisions in the sclera of an eye to create a scleral pocket that has exact dimensions to receive a scleral prosthesis.

It is an additional object of the invention to provide scleral pocket location information derived from measured values of corneal diameter, corneal radius of curvature, axial length of an eye, or the like.

It is yet another object of the invention to provide a system and method for providing precise location information to determine an optimal location on the sclera of an eye for locating a scleral pocket to receive a scleral prosthesis.

Additional objects of the present invention will become apparent from the description of the invention that follows.

The foregoing has outlined rather broadly the features and technical advantages of the present invention so that those skilled in the art may better understand the Detailed Description of the Invention that follows. Additional features and advantages of the invention will be described hereinafter that form the subject matter of the claims of the invention. Those skilled in the art should appreciate that they may readily use the conception and the specific embodiment disclosed as a basis for modifying or designing other structures for carrying out the same purposes of the present invention. Those skilled in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the invention in its broadest form.

Before undertaking the Detailed Description of the Invention, it may be advantageous to set forth definitions of certain words and phrases used throughout this patent document. The terms “include” and “comprise,” and derivatives thereof, mean inclusion without limitation; the term “or” is inclusive, meaning “and/or”; the phrases “associated with” and “associated therewith,” as well as derivatives thereof, may mean to include, be included within, interconnect with, contain, be contained within, connect to or with, couple to or with, be communicable with, cooperate with, interleave, juxtapose, be proximate to, to bound to or with, have, have a property of, or the like; and the term “controller,” “processor,” or “apparatus” means any device, system or part thereof that controls at least one operation. Such a device may be implemented in hardware, firmware or software, or some combination of at least two of the same. It should be noted that the functionality associated with any particular controller may be centralized or distributed, whether locally or remotely. Definitions for certain words and phrases are provided throughout this patent document. Those of ordinary skill should understand that in many instances (if not in most instances), such definitions apply to prior uses, as well as to future uses, of such defined words and phrases.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an isometric view of an eye having scleral pockets for receiving scleral prostheses;

FIG. 2 shows a front elevational view of an eye showing the location of four straight scleral pockets;

FIG. 3 shows a cross section of the eye of FIG. 2 along the line 3-3;

FIG. 4 shows an enlarged view of the cross section of FIG. 3 in the region indicated by the circle 4;

FIG. 5 shows a top plan view of an exemplary scleral prosthesis;

FIG. 6 shows a front elevational view of the scleral prosthesis shown in FIG. 5 showing the contoured profile of the prosthesis and two notches in the bottom of the prosthesis;

FIG. 7 shows a bottom plan view of the scleral prosthesis shown in FIG. 5 showing the location of two notches in the bottom of the prosthesis;

FIG. 8 shows an end view of the scleral prosthesis shown in FIG. 5;

FIG. 9 shows a top perspective view of the scleral prosthesis shown in FIG. 5 showing the top and one side and one end of the prosthesis;

FIG. 10 shows a bottom perspective view of the scleral prosthesis shown in FIG. 5 showing the bottom and one side of the prosthesis;

FIG. 11 shows a perspective view of a surgical tool constructed for making incisions in the sclera of an eye to create a scleral pocket to receive a scleral prosthesis;

FIG. 12 shows a surgical tool controller for controlling the operation of the surgical tool of the present invention and a foot switch for activating the surgical tool;

FIG. 13 shows an end view of the surgical tool of the present invention showing a control cable receptacle capable of receiving a control cable to supply electrical power to the surgical tool;

FIG. 14 shows a cross section of a first portion of the surgical tool showing a base housing containing a control cable receptacle, a drive motor, a gearbox, and a drive shaft capable of being rotated by the drive motor;

FIG. 15 shows a schematic circuit diagram illustrating how electrical power is supplied to the drive motor of the surgical tool;

FIG. 16 shows a cross section of a second portion of the surgical tool showing a drive shaft housing mounted within an end of the base housing of the surgical tool, and showing a blade mount housing mounted on the drive shaft housing an angle to a central axis of the drive shaft housing;

FIG. 17 shows a more detailed cross sectional view of the interconnection of the drive shaft housing and the blade mount housing shown in FIG. 16;

FIG. 18 shows a top plan view of a blade of the surgical tool;

FIG. 19 shows a side view of the blade shown in FIG. 18;

FIG. 20 shows a perspective view of the blade shown in FIG. 18;

FIG. 21 shows a side view of the drive shaft housing and the blade mount housing and the blade of the surgical tool;

FIG. 22 shows a perspective view of the drive shaft housing and an end view of the blade mount housing of the surgical tool;

FIG. 23 shows a top view illustrating how the surgical tool is to be positioned over an eye to make incisions in the sclera of the eye;

FIG. 24 shows a side view illustrating how the surgical tool is to be positioned over an eye to make incisions in the sclera of the eye;

FIG. 25 shows a perspective view of an alternate advantageous embodiment of a blade guide of the surgical tool to guide the motion of a blade when the blade is rotated to make incisions in the sclera of an eye;

FIG. 26 shows an end view of the blade guide shown in FIG. 25;

FIG. 27 shows an end view of the blade mount housing and blade guide and blade placed in contact with an eye showing how a blade passes through the blade guide when the blade is rotated to make incisions in the sclera of an eye;

FIG. 28 shows a side view of an end portion of the blade mount housing showing a portion of the blade guide that is placed in contact with an eye during the process of making incisions in the sclera of the eye;

FIG. 29 shows how a blade moves through the blade guide shown in FIG. 28 during the process of making incisions in the sclera of the eye;

FIG. 30 shows and exemplary scleral tissue fixation tool;

FIG. 31 shows a perspective view of an advantageous embodiment of a fixation end of a scleral tissue fixation tool;

FIG. 32 shows a side view of an alternate advantageous embodiment of a fixation end of a scleral tissue fixation tool;

FIG. 33 shows a side view of an alternative advantageous embodiment of a blade guide of the surgical tool comprising an interior vacuum chamber;

FIG. 34 shows a perspective view of the blade guide shown in FIG. 33;

FIG. 35 shows a side view of an alternative advantageous embodiment of a blade guide of the surgical tool comprising an interior vacuum chamber showing the operation of the vacuum chamber blade guide;

FIG. 36 shows a perspective view of a vacuum supply line coupled to the vacuum chamber blade guide;

FIG. 37 shows a perspective view of the surgical tool of the present invention showing the placement of a vacuum supply line along the surgical tool;

FIG. 38 shows a flow chart of an advantageous embodiment of a method for making incisions to form a scleral pocket for a scleral prosthesis;

FIG. 39 shows a flow chart of an alternate advantageous embodiment of a method for making incisions to form a scleral pocket for a scleral prosthesis;

FIG. 40 shows a first perspective view of an alternate advantageous embodiment of a blade of the surgical tool;

FIG. 41 shows a second perspective view of an alternate advantageous embodiment of a blade of the surgical tool;

FIG. 42 shows how a scleral prosthesis may be tied to an extension of an alternate advantageous embodiment of a blade of the surgical tool;

FIG. 43 shows a first perspective view of a second alternate advantageous embodiment of a blade of the surgical tool;

FIG. 44 shows a second perspective view of a second alternate advantageous embodiment of a blade of the surgical tool;

FIG. 45 shows a side view of three portions of a curved cutting blade of the second alternate advantageous embodiment of a blade of the surgical tool;

FIG. 46 shows a first perspective view of a third alternate advantageous embodiment of a blade of the surgical tool;

FIG. 47 shows a second perspective view of a third alternate advantageous embodiment of a blade of the surgical tool;

FIG. 48 shows a cross sectional side view of a curved cutting blade of the third alternate advantageous embodiment of a blade of the surgical tool;

FIG. 49 illustrates a schematic representation of the geometry of the structure of an eye;

FIG. 50 illustrates a schematic representation of distances between certain structures of the eye represented in FIG. 49;

FIG. 51 illustrates an applanation marking plate assembly;

FIG. 52 illustrates a controller that is capable of carrying out the method of the present invention; and

FIG. 53 illustrates a flow chart showing one advantageous embodiment of the method of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

FIGS. 1 through 53, discussed below, and the various embodiments used to describe this principles of the present invention in this patent document are by way of illustration only and should not be construed in any way to limit the scope of the invention. Those skilled in the art will understand that the principles of the present invention may be implemented in connection with any suitably arranged surgical tool and with any suitable surgical method.

The system and method of the present invention is designed for use with a surgical tool that is capable of making incisions in the sclera of an eye in order for the eye to receive a scleral prosthesis. Scleral prostheses are used to treat presbyopia (and other similar eye disorders) by increasing the effective working distance of the ciliary muscle of the eye. This is accomplished by increasing the distance between the ciliary muscle and the lens equator by increasing the diameter of the sclera in the region of the ciliary body.

The effective working distance of the ciliary muscle is increased by implanting in pockets surgically formed in the sclera of the eye a plurality of scleral prostheses designed to place an outward traction on the sclera in the region of the ciliary body. The relevant anatomy of the eye for locating the scleral pockets may be seen by reference to FIGS. 1-4. The outermost layer of the eye 100 comprises the white, tough sclera 102 which encompasses most of the globe and the transparent cornea 104, which constitutes the anterior segment of the outer coat. The circular junction of the cornea and sclera is the limbus 106. Within the globe of the eye, as illustrated in the cross-section shown in FIG. 3, the crystalline lens 108 is enclosed in a thin membranous capsule and is located immediately posterior to the iris 112, suspended centrally posterior to the pupil 114 on the optical axis of the eye. The lens 108 is suspended by zonules 115 extending between the lens capsule at the equator 110 of the lens 108 and the ciliary body 116. The ciliary body 116 lies just under the sclera 102 (i.e., just inwardly of the sclera 102) and is attached to the inner surface of the sclera 102. As may be seen in FIG. 3, the ciliary body 116 lies generally in a plane 130 defined by the equator 110 of the lens 108. The plane 130 can also be extended to intersect the sclera 102 whereby it forms a generally circular intersection located about two (2) millimeters posterior to the limbus 106. The external muscles 118 of the eyeball control the movement of the eye.

A generally outwardly directed traction is exerted on the sclera in the region of the ciliary body to expand the sclera 102 in that region. This expansion of the sclera 102 produces a corresponding expansion of the attached ciliary body 116 and moves the ciliary body 116 outwardly away from the equator 110 of the lens 108, generally in the plane 130 of the equator 110 of the lens 108. The sclera 102 is preferably expanded approximately in the plane of the equator 110 of the lens 108. However, any expansion of the sclera 102 in the region of the ciliary body 116, i.e., in the region of the sclera somewhat anterior or posterior to the plane of the equator 110 of the lens 108 is within the scope of the invention, provided that such expansion of the sclera 102 moves the ciliary body 116 away from the equator 110 of the lens 108. Typically, the expansion of the sclera will be accomplished in the is region from about one and one half millimeters (1.5 mm) anterior to the plane 130 of the equator 110 of the lens 108 to about two and one half millimeters (2.5 mm) posterior to that plane, i.e., from about one half millimeter (0.5 mm) to about four and one half millimeters (4.5 mm) posterior to the limbus 106. Accordingly, the anterior margin 122 of a scleral pocket 120 will be located in that region of the sclera.

An exemplary scleral pocket 120 is illustrated in FIG. 1. An incision is made in the surface of sclera 120 along the line indicated with reference numeral 131. The incision is then extended under the surface of sclera 120 between the anterior margin 122 and the posterior margin 124 of scleral pocket 120. This forms a “pocket” under the surface of sclera 102. The incision may also be extended through the surface of sclera 102 along the line indicated with reference number 132. This forms a “belt loop” type structure in the surface of sclera 102. For convenience the “pocket” type structure and the “belt loop” type structure will both be referred to as scleral pocket 120.

The scleral prosthesis 200 is designed to be placed within scleral pocket 120. Scleral prosthesis 200 within scleral pocket 120 applies an outwardly directed traction to the sclera 102 at the general position of the anterior margin 122 of the scleral pocket 120. The position of prosthesis 200 within scleral pocket 120 and its operation to expand the sclera are illustrated in FIGS. 3 and 4.

An advantageous embodiment of scleral prosthesis 200 is illustrated in FIGS. 5-10. FIG. 5 shows a plan view of the top 500 of prosthesis 200. In one advantageous embodiment, the length of prosthesis 200 is approximately five thousand five hundred microns (5500 μm) or, equivalently, approximately five and one half millimeters (5.5 mm).

FIG. 6 shows a front elevational view of the prosthesis 200 of FIG. 5 showing one side 600 of prosthesis 200. In one advantageous embodiment, the maximum height of prosthesis 200 is approximately nine hundred twenty five microns (925 μm) or, equivalently, approximately nine hundred twenty five thousandths of a millimeter (0.925 mm). A first notch 610 is located in the base 620 of prosthesis 200 at a first end of prosthesis 200. A second notch 630 is located in the base 620 of prosthesis 200 at a second end of prosthesis 200. When prosthesis 200 is located within scleral pocket 120 intraocular pressure from the interior of eye 100 pushes scleral tissue into notch 610 and into notch 630. The presence of scleral tissue in notch 610 and in notch 630 provides an anchoring mechanism that tends to prevent movement of prosthesis 200.

FIG. 7 shows a plan view of the bottom 620 of prosthesis 200. Notch 610 and notch 630 extend across the bottom 620 of prosthesis 200.

FIG. 8 shows an end view of prosthesis 200 showing one end 800 of the prosthesis 200. In one advantageous embodiment, the width of prosthesis 200 is approximately one thousand three hundred eighty microns (1380 μm) or, equivalently, approximately one and three hundred eighty thousandths millimeter (1.380 mm).

FIG. 9 shows a perspective top view of prosthesis 200. FIG. 9 shows top 500, one side 600 and one end 800 of the prosthesis 200. FIG. 10 shows a perspective bottom view of prosthesis 200. FIG. 10 shows the bottom 620 (including notches 610 and 630) and one side 600 of prosthesis 200.

Other types of scleral prosthesis 200 may be used including those types of prosthesis disclosed in the “Presbyopia and Related Eye Disorder Patent Documents” previously incorporated by reference into this patent document.

Scleral prosthesis 200 is made of a material that is sufficiently rigid to exert a force on the sclera sufficient to produce the radial expansion required by the method of the invention and that is physiologically acceptable for long-term implantation or contact with the ocular tissues. Such materials are well-known in the surgical art and include suitable metals, ceramics, and synthetic resins. Suitable metals include titanium, gold, platinum, stainless steel, nitinol, tantalum and various surgically acceptable alloys, and the like. Suitable ceramics may include crystalline and vitreous materials such as porcelain, alumina, silica, silicon carbide, high-strength glasses and the like. Suitable synthetic materials include physiologically inert materials such as poly(methyl methacrylate), polyethylene, polypropylene, poly (tetrafluoroethylene), polycarbonate, silicone resins, hydrophilic plastics, hydrophobic plastics, hypoxy-appetite, and the like. The scleral prosthesis 200 may also be made of composite materials incorporating a synthetic resin or other matrix reinforced with fibers of high strength material such as glass fibers, boron fibers or the like. Thus, scleral prosthesis 200 may be made of glass-fiber-reinforced epoxy resin, carbon fiber-reinforced epoxy resin, carbon fiber-reinforced carbon (carbon-carbon), or the like. Scleral prosthesis 200 may be made of a semi-rigid exterior and a liquid or gel filled interior so that the internal and external dimensions can be altered by injecting various amounts of liquid: water, saline, or silicone oil; or various amounts of a gel: silicone, collagen, or gelatin. The semi-rigid exterior may be made of any of the already listed materials. A preferred material for the entire scleral prosthesis 200 is surgical grade poly(methyl methacrylate). Scleral prosthesis 200 may also be made of a material that regains its shape when deformed such as a memory metal (e.g., nitinol).

Scleral prosthesis 200 may be manufactured by any conventional technique appropriate to the material used, such as machining, injection molding, heat molding, compression molding and the like.

Scleral prosthesis 200 may be foldable to facilitate insertion into a scleral belt loop or made in a plurality of parts so that it can be assembled prior to use or may be installed separately to form a complete prosthesis.

To implant scleral prosthesis 200 by hand, the surgeon locates the proper region of the sclera to be expanded by measuring a distance of preferably three and one half millimeters (3.5 mm) posterior of the limbus 106. At two millimeters (2.0 mm) clockwise and counterclockwise from each of the forty five degree (450) meridians of the eye, and three and one half millimeters (3.5 mm) posterior to the limbus 106, partial scleral thickness parallel incisions, i.e., antero-posterior incisions, are made which are one and one half millimeters (1.5 mm) long and three hundred fifty microns (350 μm) deep. Using a lamella blade the sclera is dissected until the partial thickness incisions are connected so that four scleral pockets or belt loops are made which have an anterior length of four millimeters (4.0 mm), and a length extending generally axially of the eye of one and one half millimeters (1.5 mm). Thus, each pocket or belt loop is preferably centered over the forty five degree (45°) meridian of the eye. A scleral prosthesis 200 is then inserted in each of the four scleral belt loops. This produces symmetrical scleral expansion which will produce the desired result of increasing the effective working distance of the ciliary muscle.

The location of the scleral prostheses 200 implanted in eye 100 is illustrated in FIGS. 1-4. FIG. 1 is an isometric view of an eye 100 having a globe with the relevant exterior anatomical parts indicated as discussed above.

FIG. 2 shows a front elevational view of an eye 100 showing the scleral pockets 120 formed at approximately the forty five degree (45°) meridians of the eye, i.e., approximately halfway between the vertical and horizontal meridians of the globe. This location is preferred because it avoids interference with structures of the eye that are located generally on the vertical and horizontal meridians. FIG. 2 shows the use of straight scleral pockets 120. Straight scleral pockets 120 are somewhat simpler to prepare surgically than curved scleral pockets (not shown). For many patients the use of straight scleral prostheses provide adequate treatment of presbyopia. Alternatively, curved scleral prostheses may be used as discussed in the “Presbyopia and Related Eye Disorder Patent Documents” previously incorporated by reference into this patent document.

FIG. 3 shows a cross-section of eye 100, taken along the line 3-3 in FIG. 2, showing the placement of scleral prosthesis 200 relative to the significant anatomical structures of the eye.

FIG. 3 shows the general configuration of the scleral pockets 120 and the prostheses 200 of the type illustrated in FIGS. 5-10. The anterior margins 122 of the scleral pockets 120 are located approximately in the plane 130 of the equator 110 of the lens 108. The presence of prosthesis 200 causes the portion of the sclera anterior to the scleral pocket 120 to be expanded somewhat more than the posterior portion. This places the sclera anterior to the scleral pocket 120 under a radial tension and causes it to expand from its normal diameter at that position. This scleral expansion draws with it the underlying ciliary body 116 and causes the ciliary body to be drawn away from the equator 110 of the lens 108. Accordingly, the expansion of the ciliary body 116 operates to increase the working distance of the ciliary muscle and restore, at least in part, the ability of the eye to accommodate for clear focusing on objects at different distances.

FIG. 4 shows an enlarged portion of one of the scleral pockets 120 with adjacent anatomical structures. It shows the relation of the scleral pocket 120 to the underlying structures and its location just posterior to the equator of the lens 108 and overlying the ciliary body 116.

The surgical procedures described above to make incisions within the sclera 102 of eye 100 are done by hand. That is, the surgeon makes the incisions in sclera 102 that are required to form scleral pocket 120 using standard surgical tools such as a scalpel. The surgeon must be very skilled in the use of a scalpel to make incisions that have the required precision.

However, the system and method of the present invention provide a much more efficient and precise way to determine the optimum location for the required incisions. The system and method of the present invention is designed for use with a surgical tool that is specifically designed to make very precise incisions in the sclera 102 of an eye 100 to form a scleral pocket 120.

FIG. 11 shows a perspective view of a surgical tool 1100. As will be more fully described, surgical tool 1100 is capable of making incisions in eye 100 to create a scleral pocket 120 to receive a scleral prosthesis 200 surgical tool 1100 comprises a base housing 1110 and a drive shaft housing 1120. Drive shaft housing 1120 comprises a blade mount housing 1130 that mounted on the drive shaft housing 1120 an angle to a central axis of drive shaft housing 1120. The reason for mounting blade mount housing 1130 at an angle with respect to the central axis of drive shaft housing 1120 is to facilitate the placement of blade mount housing 1130 on eye 100 during the surgical process. Lastly, blade 1140 is mounted on blade mount housing 1130.

FIG. 12 shows surgical tool 1100 and a surgical tool controller 1200 for controlling the operation of surgical tool 1100. Surgical tool 1100 is coupled to surgical tool controller 1200 through control cable 1210. Control cable 1210 provides electrical power to surgical tool 1100 under the control of surgical tool controller 1200 to power the operation of blade 1140. Control cable 1210 also provides an “earth ground” to surgical tool 1100. Surgical tool controller 1200 receives external electrical power through power cord 1220.

Foot switch 1230 is coupled to surgical tool controller 1200 through signal line 1240. When the surgeon is ready to rotate blade 1140 to make an incision in eye 100 the surgeon steps on foot switch 1230. Foot switch 1230 then sends a control signal to surgical tool controller 1200 through signal line 1240. In response, surgical tool controller 1220 activates electrical power to surgical tool 1100 to cause blade 1140 to rotate in a forward direction and make the desired incision in eye 100. The time required for blade 1140 to make an incision in eye 100 is approximately two (2) seconds. The incision is complete after blade 1140 has reached the end of its rotation in the forward direction. Surgical tool controller 1200 then automatically causes blade 1140 to rotate back out of the incision. Surgical tool 1100 is then ready to make another incision.

If the surgeon releases his or her foot from foot switch 1230 during the two (2) second time period during which the incision is being made, foot switch 1230 immediately sends a control signal to surgical tool controller 1200 through signal line 1240. In response, surgical tool controller 1220 causes the forward motion of blade 1140 to cease and then automatically rotates blade 1140 out of the incision.

Surgical tool controller 1200 comprises a switch 1250 (on/off switch 1250) for activating the operation of surgical tool controller 1200. Surgical tool controller 1200 also comprises indicator lights 1260 that indicate the operational status of surgical tool controller 1200.

FIG. 13 shows an end view of base housing 1110 of surgical tool 1100. Base housing 1110 comprises a control cable receptacle 1300 capable of receiving control cable 1210 to electrically power surgical tool 1100. In this advantageous embodiment control cable receptacle 1300 is capable of receiving four (4) individual power plugs of control cable 1210.

FIG. 14 shows a cross section of base housing 1110. Base housing 1110 comprises control cable receptacle 1300, four power lines (collectively designated 1410), drive motor 1420, gearbox 1430, and a drive shaft 1440. When control cable 1210 is placed into control cable receptacle 1300, four power plugs of control cable 1210 make contact with the four power lines 1410. As shown in FIG. 15, two of the four power lines (line 1 and line 2) are coupled to a first winding circuit (circuit A) of motor 1420. The other two of the four power lines (line 3 and line 4) are coupled to a second winding circuit (circuit B) of motor 1420.

When surgical tool controller 1200 powers up line 1 and line 2, then motor 1420 rotates in one direction (e.g., counterclockwise). When surgical tool controller 1200 powers up line 3 and line 4, then motor 1420 rotates in the other direction (e.g., clockwise). In this manner motor 1420 provides both rotational motion to rotate blade 1140 forward to make an incision in eye 100 and provides rotational motion to rotate blade 1140 backwards to remove blade 1140 from the incision made in eye 100. The two types of rotational motion will be collectively referred to as “bidirectional rotational motion.”

The rotational motion generated by motor 1420 is coupled to gearbox 1430. In one advantageous embodiment gearbox 1430 reduces the rotational speed provided by motor 1420 by a factor of sixty six (66:1). That is, the rotational speed output by gearbox 1430 is one sixty sixth ( 1/66) of the rotational speed provided to gearbox 1430 by motor 1420. This amount of rotational speed reduction is necessary to increase the torque and because the rotational speed provided by motor 1420 is too great to be used to rotate blade 1140 directly. The rotational output from gearbox 1430 is coupled to drive shaft 1440 of base housing 1110.

FIG. 16 shows a cross sectional view of drive shaft housing 1120 mounted within base housing 1110 and a cross sectional view of blade mount housing 1130. Blade 1140 is not shown in FIG. 16. Drive shaft housing 1120 seats within a receptacle of base housing 1110 and is held in place by conventional means such as a screw 1610. O-ring 1620 seals the juncture between the receptacle of base housing 1110 and drive shaft housing 1120.

Drive shaft housing 1120 comprises drive shaft 1630. Drive shaft 1630 is supported within drive shaft housing 1120 by conventional bearings. As shown in FIG. 16, drive shaft 1630 is coupled to drive shaft 1440 of base housing 1110. The coupling of drive shaft 1630 and drive shaft 1440 is supported by conventional bearings. Drive shaft 1440 rotates drive shaft 1630.

Blade mount housing 1130 comprises drive shaft 1640. Drive shaft 1640 is supported within blade mount housing 1130 by conventional bearings. As shown in FIG. 16, drive shaft 1640 is coupled to drive shaft 1630 of drive shaft housing 1120 at an angle. As shown in greater detail in FIG. 17, a beveled gear 1710 of drive shaft 1630 engages a beveled gear 1720 of drive shaft 1640. As drive shaft 1630 is rotated, the rotational motion of beveled gear 1720 of drive shaft 1630 is imparted to beveled gear 1720 of drive shaft 1640. The rotational motion of drive shaft 1640 is used to rotate blade 1140 (not shown in FIGS. 16 and 17) mounted on blade mount housing 1130.

Base plate 1730 seats within an end of blade mount housing 1130 and is held in place by conventional means such as a screw 1740. Drive shaft 1640 extends through an aperture in base plate 1730 so that base plate 1730 also provides support for drive shaft 1640. Conventional means such as a screw 1750 may be used to secure blade 1140 to drive shaft 1640. Screw 1750 may also serve as an extension 1750 of drive shaft 1640 onto which blade 1140 may be mounted. Base plate 1730 comprises portions forming a blade guide 1760 for guiding the rotation of blade 1140 and for stopping the rotation of blade 1140 after blade 1140 has been rotated by a desired amount.

The blade 1140 of surgical tool 1100 is shown in FIGS. 18-20. FIG. 18 shows a top plan view of blade 1140. FIG. 19 shows a side view of blade 1140. FIG. 20 shows a perspective view of blade 1140. Blade 1140 comprises support arm 1810 adapted to be mounted on an end of drive shaft 1640 of blade mount housing 1130. Blade 1140 also comprises a curved cutting blade 1820 for making an incision in the sclera 102 of eye 100. In an advantageous embodiment of the invention, (1) support arm 1810 and curved cutting blade 1820 are formed as a unitary structure, and (2) curved cutting blade 1820 is circularly curved, and (3) curved cutting blade 1820 has end portions defining a tapered cutting point 1830.

When drive shaft 1640 is rotated, support arm 1810 rotates around the axis of drive shaft 1640. This causes curved cutting blade 1820 to rotate around the axis of drive shaft 1640. The dimensions of curved cutting blade 1820 are chosen so that the incision made by curved cutting blade 1820 in the sclera 102 of eye 100 has the desired dimensions to form scleral pocket 120. Scleral pocket 120 should be approximately four millimeters (4.0 mm) long, one and one half millimeters (1.5 mm) wide, and four hundred microns (400 μm) deep. Four hundred microns (400 μm) is equivalent to four tenths of a millimeter (0.4 mm).

FIG. 21 shows an external side view of drive shaft housing 1120 and blade mount housing 1130 and blade 1140. Aperture 2110 is provided to receive screw 1610 to fasten drive shaft housing 1120 within base housing 1110. Groove 2120 is provided to receive O-ring 1620 to seal the juncture between the receptacle of base housing 1110 and drive shaft housing 1120. Aperture 2130 is provided to receive screw 1740 to fasten base plate 1730 within blade mount housing 1130.

An external reference line 2140 is marked on the surface of blade mount housing 1130. Line 2140 is located five and one half millimeters (5.5 mm) from the end of blade mount housing 1130. Line 2140 allows the surgeon to properly align blade 1140 during the surgical process. The surgeon aligns line 2140 with the limbus 106 of eye 100. This alignment properly positions blade 1140 to make an incision at the desired location on sclera 102 of eye 100.

FIG. 22 shows a perspective view of drive shaft housing 1120 and an end view of blade mount housing 1130. Base plate 1730 forms the end of blade mount housing 1130. The components of blade 1140 are shown separately as support arm 1810 and curved cutting blade 1820. Support arm 1810 is mounted on drive shaft 1640 by snapping an end of support arm 1810 onto an extension 1750 of drive shaft 1640. In an alternative embodiment, support arm 1810 may be mounted on drive shaft 1640 using conventional means such as a screw.

Support arm 1810 is shown rotated forward to a position where it has abutted an edge of blade guide 1760. In this position curved cutting blade 1820 has completed its rotation and would have completed an incision if it has been adjacent to eye 100. Blade guide 1760 also guides the rotation of blade 1140. Blade guide 1760 is formed having a circularly shaped surface 2220 that is concentric with curved cutting blade 1820. The length of support arm 1810 supports curved cutting blade 1820 at a distance that is approximately four hundred microns (400 μm) away from the circularly shaped surface 2220 of blade guide 1760.

At the start of the surgical process the surgeon places the circularly shaped surface 2220 of blade guide 1760 on the sclera 102 of eye 100. The surgeon then begins the rotation of blade 1140 by stepping on foot switch 1230. As long as the surgeon is stepping on foot switch 1230 blade 1140 continues to advance in a forward direction as support arm 1810 of blade 1140 rotates curved cutting blade 1820. Curved cutting blade 1820 then passes through sclera 102 of eye 100 at a depth of approximately four hundred microns (400 μm) to make the desired incision. The surgeon removes his or her foot from foot switch 1230 if the surgeon determines that it is desirable to stop the rotation of blade 1140. Surgical tool controller 1200 will immediately stop the rotation of blade 1140 and will then automatically rotate blade 1140 out of the incision.

The components of blade 1140 (support arm 1810 and curved cutting blade 1820) may also be rotated back to abut the safety stop 2210. Blade guide 1760 and safety stop 2210 limit the rotational range of blade 1140 to only the rotation needed to perform the desired incisions.

FIG. 23 shows a top view illustrating how surgical tool 1100 is to be positioned over eye 100 to make incisions in the sclera 102 of eye 100. Eye 100 comprises sclera 102, iris 112, pupil 114, and limbus 106 (the boundary between sclera 102 and iris 112). Iris 114 and portions of limbus 106 are shown in dotted outline in FIG. 23 because they are obscured by drive shaft housing 1120 and blade mount housing 1130. As previously mentioned, the surgeon aligns line 2140 on blade mount housing 1130 with the limbus 106 of eye 100. This alignment properly positions blade 1140 to make an incision at the desired location on sclera 102 of eye 100.

FIG. 24 shows a side view illustrating how surgical tool 1100 is to be positioned over eye 100 to make incisions in the sclera 102 of eye 100. The surgeon aligns line 2140 on blade mount housing 1130 with limbus 106 of eye 100. As described with reference to FIG. 23 this alignment properly positions blade 1140. The reason for mounting blade mount housing 1130 at an angle with respect to the central axis of drive shaft housing 1120 is now apparent. It is to facilitate the placement of blade mount housing 1130 on eye 100 during the surgical process.

FIG. 25 shows a perspective view of an alternate advantageous embodiment 2500 of blade guide 1760. Blade guide 2500 is mounted on base plate 1730. In this embodiment blade guide 2500 comprises an end portion 2510 forming a first blade slot 2520 on a first end of blade guide 2500. Blade guide 2500 also comprises an end portion 2530 forming a second blade slot 2540 on a second end of blade guide 2500. Blade guide 2500 operates in the same manner as blade guide 1760 except that the end portions, 2510 and 2530, of blade guide 2500 provide additional external protection for curved cutting blade 1820 of blade 1140. End portions, 2510 and 2530, may also be seated against sclera 102 of eye 100 during the surgical process to provide additional peripheral contact between blade guide 2500 and sclera 102 and to ensure a proper length for an incision.

FIG. 26 shows an end view of blade guide 2500. Blade guide 2500 is formed having a circularly shaped surface 2550 that is concentric with curved cutting blade 1820. The length of support arm 1810 supports curved cutting blade 1820 at a distance that is approximately four hundred microns (400 μm) away from the circularly shaped surface 2550 of blade guide 2500.

At the start of the surgical process the surgeon places circularly shaped surface 2550 of blade guide 2500 on the sclera 102 of eye 100. A pressure sensor 2560 within blade guide 2500 senses the pressure of the sclera 102 against the circularly shaped surface 2550 of blade guide 2500. A pressure sensor control line (not shown) connects pressure sensor 2560 to surgical tool controller 1200. Pressure sensor 2560 senses whether there is sufficient pressure between the surface of sclera 102 and the circularly shaped surface 2550 of blade guide 2500. If there is not sufficient pressure then any incision made by blade 1140 would be too shallow. If pressure sensor 2560 does not detect sufficient pressure then surgical tool controller 1200 will not allow blade 1140 of surgical tool 1100 to rotate. If pressure sensor 2560 does detect sufficient pressure then surgical tool controller 1200 will allow blade 1140 of surgical tool 1100 to rotate.

The surgeon begins the rotation of blade 1140 by stepping on foot switch 1230. As long as the surgeon is stepping on foot switch 1230 blade 1140 continues to advance in a forward direction as support arm 1810 of blade 1140 rotates curved cutting blade 1820. Curved cutting blade 1820 then passes through sclera 102 of eye 100 at a depth of approximately four hundred microns (400 μm) to make the desired incision. The surgeon removes his or her foot from foot switch 1230 if the surgeon determines that it is desirable to stop the rotation of blade 1140. Surgical tool controller 1200 will immediately stop the rotation of blade 1140 and will then automatically rotate blade 1140 out of the incision.

FIG. 27 shows an end view of blade guide 2500 showing how curved cutting blade 1820 passes through first blade slot 2520 of blade guide 2500, and through sclera 102 of eye 100, and through second blade slot 2540 of blade guide 2500 when support arm 1810 of blade 1140 is rotated. Curve 2710 represents the surface contour of sclera 102 of eye 100 before blade guide 2500 is placed in contact with eye 100. Curve 2720 represents the surface contour of eye 100 after blade guide 2500 is placed in contact with sclera 102 of eye 100. Pressure applied to keep blade guide 2500 in contact with sclera 102 of eye 100 temporarily makes the surface contour of the sclera 102 of eye 100 concave during the incision process.

FIG. 28 shows a side view of an end portion of blade mount housing 1130 showing the surface 2550 of blade guide 2500 that is placed in contact with sclera 102 of eye 100. Pressure sensor 2560 in blade guide 2500 is shown in dotted outline. In this view curved cutting blade 1820 of blade 1140 is retracted. First blade slot 2520 and second blade slot 2540 of blade guide 2500 are visible.

FIG. 29 also shows a side view of an end portion of blade mount housing 1130 showing the surface 2550 of blade guide 2500 that is placed in contact with sclera 102 of eye 100. As before, pressure sensor 2560 in blade guide 2500 is shown in dotted outline. In this view curved cutting blade 1820 of blade 1140 has begun to be rotated through first blade slot 2520. Curved cutting blade 1820 is the process of rotating across surface 2550 of blade guide 2500 and is proceeding toward second blade slot 2540 of blade guide 2500. FIG. 29 shows how curved cutting blade 1820 moves through blade guide 2500 during the process of making incisions in sclera 102 of eye 100.

The counterclockwise motion of the curved cutting blade 1820 hitting the surface of the sclera 102 of eye 100 tends to push surgical tool 1100 in the opposite direction causing surgical tool 1100 to translate opposite to the tangent force generated by curved cutting blade 1820. It is therefore necessary to firmly hold the surface of the sclera 102 against the surgical tool 1100 during the process of making the incision.

In one advantageous embodiment of the invention, a scleral tissue fixation tool 3000 is utilized to restrain the movement of surgical tool 1100. As shown in FIG. 30, scleral tissue fixation tool 3000 generally comprises a shaft 3010 having a fixation end 3020 that is capable of engaging and holding a portion of the surface of sclera 102. Scleral tissue fixation tool 3000 applies a force opposite to the tangent force generated by the curved cutting blade 1820 coming in contact with the sclera 102. The shaft 3010 is manually held and operated by the surgeon during the process of making an incision so that surgical tool 1100 does not move.

In one advantageous embodiment, scleral tissue fixation tool 3000 is approximately fifteen centimeters (15.0 cm) to twenty centimeters (20.0 cm) long and approximately one and one half millimeters (1.5 mm) wide. FIG. 31 shows a perspective view of fixation end 3020 of scleral tissue fixation tool 3000. Fixation end 3020 comprises a first fixation barb 3110 formed on a first side of the end of shaft 3010. First fixation barb 3110 is formed by slicing and lifting up an end portion of shaft 3010. The amount of separation of first fixation barb 3110 from the end of shaft 3010 is in the range from three tenths of a millimeter (0.30 mm) to four tenths of a millimeter (0.40 mm).

Fixation end 3020 also comprises a second fixation barb 3120 formed on a second side of the end of shaft 3010. Second fixation barb 3120 is formed by slicing and lifting up an end portion of shaft 3010. The amount of separation of second fixation barb 3120 from the end of shaft 3010 is the same as the amount of separation of first fixation barb 3110.

To restrain the translational movement of surgical tool 1100 the surgeon uses scleral tissue fixation tool 3000 to engage and hold a portion of sclera 102 near the first blade slot 2520 of blade guide 2500. First blade slot 2520 is where curved cutting blade 1820 first impacts sclera 102 and tends to cause translation of surgical tool 1100. The surgeon places the fixation end 3020 of the scleral tissue fixation tool 3000 onto the sclera 102 and twists shaft 3010 to the right to engage first fixation barb 3110 and second fixation barb 3120 into sclera 102. The surgeon holds the shaft 3010 against surgical tool 1100 during the incision process. After the incision has been made the surgeon releases the scleral tissue fixation tool 3000 from sclera 102 by twisting shaft 3010 to the left to disengage the grip of fixation barbs, 3110 and 3120.

The scleral tissue fixation tool 3000 shown in FIG. 31 is a “right twist” tool. It engages by twisting shaft 3010 to the right and disengages by twisting shaft 3010 to the left.

FIG. 32 shows an alternative advantageous embodiment of scleral tissue fixation tool 3000. The scleral tissue fixation tool 3000 shown in FIG. 32 is a “left twist” tool. It engages by twisting shaft 3010 to the left and disengages by twisting shaft 3010 to the right. Otherwise, the scleral tissue fixation tool 3000 shown in FIG. 32 is identical to the scleral tissue fixation tool 3000 shown in FIG. 31. It comprises a first fixation barb 3210 and a second fixation barb 3220. The amount of separation 3230 of first fixation barb 3210 from the end of shaft 3010 is in the range from three tenths of a millimeter (0.30 mm) to four tenths of a millimeter (0.40 mm). The amount of separation of second fixation barb 3220 from the end of shaft 3010 is the same as the amount of separation of first fixation barb 3210.

In an alternate advantageous embodiment of the invention, a special type of vacuum operated blade guide 3300 is utilized to restrain the movement of the sclera 102 and the translational movement of surgical tool 1100 generated from the impact of the curved cutting blade 1820. As will be more fully described, a vacuum is applied to seat blade guide 330 against sclera 102 during the process of making an incision.

FIG. 33 shows an end view of blade guide 3300. Blade guide 3300 is mounted on base plate 1730. In this embodiment blade guide 3300 comprises an end portion 3310 forming a first blade slot 3320 on a first end of blade guide 3300. Blade guide 3300 also comprises an end portion 3330 forming a second blade slot 3340 on a second end of blade guide 3300. The end portions, 3310 and 3330, of blade guide 3300 provide additional external protection for curved cutting blade 1820 of blade 1140. End portions, 3310 and 3330, are seated against sclera 102 of eye 100 during the surgical process to provide additional peripheral contact between blade guide 3300 and sclera 102 to ensure proper scleral pocket length.

Blade guide 3300 is formed having a circularly shaped surface 3350 that is concentric with curved cutting blade 1820. The length of support arm 1810 supports curved cutting blade 1820 at a distance that is approximately four hundred microns (400 μm) away from the circularly shaped surface 3350 of blade guide 3300.

At the start of the surgical process the surgeon places circularly shaped surface 3350 of blade guide 3300 on the sclera 102 of eye 100. A pressure sensor 3390 within blade guide 3300 senses the pressure of the sclera 102 against the circularly shaped surface 3350 of blade guide 3300. A pressure sensor control line (not shown) connects pressure sensor 3390 to surgical tool controller 1200. Pressure sensor 3390 senses whether there is sufficient pressure between the surface of sclera 102 and the circularly shaped surface 3350 of blade guide 3300. If there is not sufficient pressure then any incision made by blade 1140 would be too shallow. If pressure sensor 3390 does not detect sufficient Pressure then surgical tool controller 1200 will not allow blade 1140 of surgical tool 1100 to rotate. If pressure sensor 3390 does detect sufficient pressure then surgical tool controller 1200 will allow blade 1140 of surgical tool 1100 to rotate.

The surgeon begins the rotation of blade 1140 by stepping on foot switch 1230. As long as the surgeon is stepping on foot switch 1230 blade 1140 continues to advance in a forward direction as support arm 1810 of blade 1140 rotates curved cutting blade 1820. Curved cutting blade 1820 then passes through sclera 102 of eye 100 at a depth of approximately four hundred microns (400 μm) to make the desired incision. The surgeon removes his or her foot from foot switch 1230 if the surgeon determines that it is desirable to stop the rotation of blade 1140. Surgical tool controller 1200 will immediately stop the rotation of blade 1140 and will then automatically rotate blade 1140 out of the incision.

Blade guide 3300 also comprises portions that form a vacuum chamber 3360 within the interior of blade guide 3300. Blade guide 3300 also comprises portions that form a plurality of access ports, 3365, 3370, and 3375, that extend from vacuum chamber 3360 through the circularly shaped surface 3350 of blade guide 3300 to apply vacuum to the surface of sclera 102. Blade guide 3300 also comprises a vacuum coupling 3380 capable of being connected to a vacuum supply line (not shown in FIG. 33).

FIG. 34 shows a perspective view of blade guide 3300 showing end portion 3310 and first blade slot 3320. FIG. 34 also shows end portion 3330 and second blade slot 3340. Vacuum coupling 3380 extends from the exterior of blade guide 3300 to vacuum chamber 3360 (not shown in FIG. 34) located within blade guide 3300.

FIG. 35 shows an end view of blade guide 3300 showing the placement of circularly shaped surface 3350 of blade guide 3300 on the surface of sclera 102. For clarity end portion 3310, first blade slot 3320, end portion 3330 and second blade slot 3340 previously shown in FIG. 34 have been omitted from FIG. 35.

Vacuum coupling 3380 is coupled to a vacuum supply line 3500. Vacuum supply line 3500 provides a vacuum to vacuum chamber 3360. The vacuum causes air to pass through access ports 3365, 3370, and 3375 into vacuum chamber 3360 (shown by arrows in FIG. 35) when access ports 3365, 3370, and 3375 are open to the atmosphere. When circularly shaped surface 3350 of blade guide 3300 is placed in contact with the surface of sclera 102 the vacuum in vacuum chamber 3360 causes sclera 102 to adhere to the surface of circularly shaped surface 3350. The adhesion caused by the vacuum in vacuum chamber 3360 restrains the movement of sclera 102 when curved cutting blade 1820 is rotated into sclera 102 to make an incision.

This alternate advantageous embodiment requires vacuum supply line 3500 be to connected to a vacuum supply (not shown). FIG. 36 shows how vacuum supply line 3500 is connected to vacuum coupling 3380 of blade guide 3300. FIG. 37 shows how vacuum supply line 3500 may be externally located along the length of surgical tool 1100.

FIG. 38 shows a flow chart of an advantageous embodiment of a method for making incisions to form a scleral pocket 120 for a scleral prosthesis 200. The steps of the method are generally denoted with reference numeral 3800. Blade mount housing 1130 of surgical tool 1100 is positioned over sclera 102 of eye 100 by aligning external reference line 2140 of blade mount housing 1130 with limbus 106 of eye 100 (step 3810). Then blade mount housing 1130 and blade 1140 are placed into contact with sclera 102 (step 3820).

The movement of sclera 102 and surgical tool 1100 is then restrained by engaging and holding sclera 102 with scleral tissue fixation tool 3000 (step 3830). Surgical tool 1100 rotates curved cutting blade 1820 through sclera 102 to make an incision to form scleral pocket 120 (step 3840). When the incision is complete surgical tool 110 rotates curved cutting blade 1820 back out of the incision made through sclera 102 (step 3850). Then sclera 102 is released by disengaging scleral tissue fixation tool 3000 (step 3860). The incision forms scleral pocket 120 to receive scleral prosthesis 200.

FIG. 39 shows a flow chart of an alternate advantageous embodiment of a method for making incisions to form a scleral pocket 120 for a scleral prosthesis 200. The steps of the method are generally denoted with reference numeral 3900. Blade mount housing 1130 of surgical tool 1100 is positioned over sclera 102 of eye 100 by aligning external reference line 2140 of blade mount housing 1130 with limbus 106 of eye 100 (step 3910). Then blade mount housing 1130 and blade 1140 are placed into contact with sclera 102 (step 3920).

The movement of sclera 102 and surgical tool 1100 is then restrained by engaging and holding sclera 102 with a vacuum from vacuum chamber 3360 of blade guide 33000 (step 3930). Surgical tool 1100 rotates curved cutting blade 1820 through sclera 102 to make an incision to form scleral pocket 120 (step 3940). When the incision is complete surgical tool 110 rotates curved cutting blade 1820 back out of the incision made through sclera 102 (step 3950). Then sclera 102 is released by venting the vacuum in vacuum chamber 3360 of blade guide 3300 (step 3960). The incision forms scleral pocket 120 to receive scleral prosthesis 200.

FIG. 40 shows a first perspective view of an alternate advantageous embodiment of blade 1140 of surgical tool 1100 of the present invention comprising support arm 4010 and curved cutting blade 4020. In the embodiment of blade 1140 shown in FIGS. 18-20 support arm 1810 and curved cutting blade 1820 are formed as a unitary structure. In the embodiment of blade 1140 shown in FIG. 40 curved cutting blade 4020 is detachable from support arm 4010.

FIG. 41 shows a second perspective view of the alternate advantageous embodiment of blade 1140 shown in FIG. 40. Curved cutting blade 4020 comprises an extension 4030 having portions that form an aperture 4040 through extension 4030. As shown in FIG. 42, a string-like connector 4200 (e.g., a plastic fiber 4200) may be used to tie a scleral prosthesis 200 to extension 4030. Surgical tool 1100 rotates support arm 4010 and causes curved cutting blade 4020 to pass through sclera 102 as previously described.

However, in this advantageous embodiment of the invention curved cutting blade 4020 is disconnected from support arm 4010 after the incision in sclera 102 has been made. Curved cutting blade 4020 remains within the incision. Surgical tool 1100 is removed. Then the leading edge of curved cutting blade 4020 is withdrawn from the incision in the forward direction. Because curved cutting blade 4020 is tied to scleral prosthesis 200 by string-like connector 4200 the withdrawal of curved cutting blade 4020 from the incision pulls scleral prosthesis 200 into the incision. Curved cutting blade 4020 acts as a needle pulling the string-like connector 4200. Curved cutting blade 4020 is then re-attached to support arm 4010 for use in making the next incision of sclera 102.

FIG. 43 shows a first perspective view of a second alternate advantageous embodiment of blade 1140 of surgical tool 1100 of the present invention comprising support arm 4310 and curved cutting blade 4320. In the embodiment of blade 1140 shown in FIGS. 18-20 support arm 1810 and curved cutting blade 1820 are formed as a unitary structure. In the embodiment of blade 1140 shown in FIG. 43 curved cutting blade 4320 is detachable from support arm 4310.

In addition a central portion 4330 of curved cutting blade 4320 is detachable from the other portions of curved cutting blade 4320. Curved cutting blade 4320 comprises three portions. The three portions are (1) detachable central portion 4330, and (2) detachable tip 4340, and (3) blade portion 4350. FIG. 44 shows a second perspective view of the second alternate advantageous embodiment of blade 1140 shown in FIG. 43. Central portion 4330 is shown shaded in FIGS. 43 and 44.

Curved cutting blade 4320 is rotated into sclera 102 to form an incision in the manner previously described. The curved cutting blade 4320 is detached from support arm 4310 while curved cutting blade 4320 remains within the incision. FIG. 45 shows a side view of the three portions (4330, 4340, 4350) of curved cutting blade 4320 within an incision.

Then detachable tip 4340 is detached from detachable central portion 4330 (e.g., by forceps) and is removed from the incision. Then blade portion 4350 is detached from detachable central portion 4330 and is removed from the incision. Detachable central portion 4330 is left within the incision to serve as a scleral prosthesis 200.

FIG. 46 shows a first perspective view of a third alternate advantageous embodiment of blade 1140 of surgical tool 1100 comprising support arm 4610 and curved cutting blade 4620. In the embodiment of blade 1140 shown in FIGS. 18-20 support arm 1810 and curved cutting blade 1820 are formed as a unitary structure. In the embodiment of blade 1140 shown in FIG. 46 curved cutting blade 4620 is detachable from support arm 4610.

In addition curved cutting blade 4620 has portions that define a conduit 4630 through curved cutting blade 4620. Slidably disposed within conduit 4630 is scleral prosthesis 200. Plunger 4640 is also slidably disposed within conduit 4630. Plunger 4630 abuts scleral prosthesis 200. FIG. 47 shows a second perspective view of the third alternate advantageous embodiment of blade 1140 shown in FIG. 46. Scleral prosthesis 200 is shown shaded in FIGS. 46 and 47.

Curved cutting blade 4620 is rotated into sclera 102 to form an incision in the manner previously described. The curved cutting blade 4620 is detached from support arm 4610 while curved cutting blade 4620 remains within the incision. FIG. 48 shows a cross sectional side view of curved cutting blade 4620. Curved cutting blade 4620 is withdrawn from the incision. Plunger 4640 remains in place against scleral prosthesis 200 as curved cutting blade 4620 is withdrawn from the incision. Plunger 4640 prevents scleral prosthesis 200 from being withdrawn from the incision. Plunger 4640 finally pushes scleral prosthesis 200 out of conduit 4630 and into the incision. Then plunger 4640 is withdrawn from the incision leaving scleral prosthesis 200 properly placed within the incision.

In one advantageous embodiment, scleral prosthesis 200 is capable of being filled with a fluid. Scleral prosthesis 200 is filled with a fluid after scleral prosthesis 200 has been placed within the incision in order to increase the size of scleral prosthesis 200.

FIG. 49 illustrates a schematic representation of the geometry of the structure of eye 100. FIG. 50 illustrates a schematic representation of distances between certain structures of eye 100. The system and method of the present invention for determining a position for scleral pocket 120 in the sclera 102 of eye 100 will be described with reference to the geometry of the structures of eye 100 shown in FIG. 49 and in FIG. 50.

A cross section of eye 100 is represented by two intersecting circles 4910 and 4920. Circle 4910 represents the curvature of the cornea 104 of eye 100. Although the cornea 104 of eye 100 is slightly flatter at its periphery that at its center, the cornea 104 will be assumed to be spherical. This assumption does not significantly affect the accuracy of the calculations for determining the position for scleral pocket 120. The radius of circle 4910 is designated with the letter C.

Circle 4920 represents the curvature of the sclera 102 of eye 100. The radius of circle 4920 is designated with the letter D. The center of circle 4920 represents the center of a scleral shell 102 that represents the sclera 102 of eye 100. The circumference of circle 4910 and the circumference of circle 4920 intersect at point 4930 and point 4940. It is understood that FIG. 1 represents a cross section of eye 100 and that point 4930 and point 4940 are only two of the points on the corneal diameter of eye 100. The plane 4950 that is perpendicular to the axis of eye 100 and that passes through point 4930 and point 4940 on the corneal diameter is referred to as the corneal plane 4950.

The diameter of the cornea 104 is designated with the letter A. The distance from the anterior central corneal surface to the corneal plane 4950 is designated with the letter E. The distance from the corneal plane 4950 to the center of circle 4920 (i.e., the center of the scleral shell 102) is designated with the letter F. The axial length of eye 100 is designated with the letter B. As shown in FIG. 1, the axial length B is equal to the sum of the distances D, F and E.

The method of the present invention first determines the value of radius D of circle 4920 from values that can be empirically measured. The values of the corneal diameter A, the mean radius of curvature C of the cornea, and the axial length B of the eye 100 can be measured. Specifically, an ultrasound biomicroscope may suitably be used to determine a value for the corneal diameter A. Mean central keratometry may be used to determine a value for the mean radius of curvature C of the cornea. An ultrasound biomicroscope or an A-scan may be used to determine a value of the axial length B of eye 100. Of course, those skilled in the art will understand that alternate approaches may be used in lieu of any of the same.

A measured value of corneal diameter A may be twelve millimeters (12.00 mm). A measured value for the radius of curvature C of the cornea may be eight millimeters (8.00 mm). A measured value for the axial length B may be twenty-two and three tenths millimeters (22.3 mm). A value of the radius D of the scleral shell may be calculated from these values.

From the geometry of eye 100 shown in FIG. 1, the axial length B is equal to the sum of the distances D, F and E. The value of the distance E can be determined from the values of A and C by using the Pythagorean theorem:

$\begin{matrix} {E = {C - \left\lbrack {C^{2} - \left( {A/2} \right)^{2}} \right\rbrack^{\frac{1}{2}}}} & (1) \end{matrix}$

The value of the distance F can be determined from the values of A and D by using the Pythagorean theorem:

$\begin{matrix} {F = \left\lbrack {D^{2} - \left( {A/2} \right)^{2}} \right\rbrack^{\frac{1}{2}\;}} & (2) \end{matrix}$

The value of D can then be determined by using the fact that the axial length B is equal to the sum of the distances D, F and E.

$\begin{matrix} {B = {D + \left\lbrack {D^{2} - \left( {A/2} \right)^{2}} \right\rbrack^{\frac{1}{2}} + C - \left\lbrack {C^{2} - \left( {A/2} \right)^{2}} \right\rbrack^{\frac{1}{2}}}} & (3) \end{matrix}$

Inserting the measured values for A, B and C into Equation (3) and solving for D gives a value for D of ten and seven tenths millimeters (10.7 mm).

Now consider the structures of eye 100 shown in FIG. 2. From empirical measurements it is known that the distance from the anterior central corneal surface to the anterior surface of the lens 108 is three and seven tenths millimeters (3.7 mm). This distance is designated with the letter G. It is also known from empirical measurements that the distance from the anterior central corneal surface to the posterior surface of the lens 108 is seven and seven tenths millimeters (7.7 mm). The thickness of the lens 108 is the difference of these two distances. The thickness of the lens 108 is given by 7.7 mm minus 3.7 mm. The thickness of the lens 108 is four millimeters (4.0 mm). The thickness of the lens 108 is designated with the letter J. Symbolically, the thickness J of lens 108 equals H-G.

It is known that the position of the lens equatorial plane 130 (with respect to the anterior surface of the lens 108) can be determined by multiplying the thickness of the lens 108 by an empirical percentage that has been previously determined from measurements made on the relative position of the lens equator of cadaver eyes. Assume that the present measurement is being made for an eye 100 of a fifty year old person. From empirical measurements the appropriate percentage is forty percent (40%). The position of the lens equatorial plane 130 is forty percent (40%) of four millimeters (4.0 mm) (i.e., one and six tenths millimeters (1.6 mm)) from the anterior surface of the lens 108.

This means that the distance from the anterior central corneal surface to the lens equatorial plane 130 is given by the sum of the distance G and the distance 1.6 mm. As previously noted, the value of G is 3.7 mm. Therefore, the distance from the anterior central corneal surface to the lens equatorial plane 130 is five and three tenths millimeters (5.3 mm).

From FIG. 49 it is known that the distance E from the anterior central corneal surface to the corneal plane 4950 is given by Equation (1). Inserting the measured values for A and C into Equation (1) and solving for E gives a value for E of two and seven tenths millimeters (2.7 mm).

The distance between the corneal plane 4950 and the lens equatorial plane 130 is designated by the letter L. The distance L may be obtained by subtracting the distance from the anterior central corneal surface to the corneal plane 4950 (i.e., the distance E) from the distance from the anterior central corneal surface to the lens equatorial plane 130. The distance L equals 5.3 mm minus 2.7 mm. That is, the distance L equals two and six tenths millimeters (2.6 mm).

From FIG. 49 it is also known that the distance F from the center of the scleral shell 102 to the corneal plane 4950 is given by Equation (2). Inserting the measured value for A and the calculated value for D into Equation (2) and solving for F gives a value for F of eight and eighty six hundredths millimeters (8.86 mm).

The distance from the center of the scleral shell 102 to the lens equatorial plane 130 is designated by the letter K. The distance K may be obtained by subtracting the distance between the corneal plane 4950 and the lens equatorial plane 130 (i.e., the distance L) from the distance from the center of the scleral shell 102 to the corneal plane 4950. The distance K equals 8.86 mm minus 2.6 mm. That is, the distance K equals six and twenty six hundredths millimeters (6.26 mm).

The distance from the axis of eye 100 to the point where the lens equatorial plane 130 crosses the sclera 102 is designated by the letter M. The value of the distance M can be determined from the values of D and K by using the Pythagorean theorem:

$\begin{matrix} {M = \left\lbrack {D^{2} - K^{2}} \right\rbrack^{\frac{1}{2}}} & (4) \end{matrix}$

Inserting the value of 10.7 mm for D and the value of 6.26 mm for K into Equation (4) and solving for M gives a value for M of eight and sixty seven hundredths millimeters (8.67 mm).

The front of the scleral pocket 120 should be placed four hundred fifty microns (450μ) posterior to the lens equatorial plane 130. Four hundred fifty microns is equivalent to four hundred fifty thousandths of a millimeter (0.450 mm). The point of location for the front of the scleral pocket 120 is designated with the letter Q in FIG. 50.

The distance from the center of the cornea 104 to the point of location for the front of the scleral pocket 120 is designated with the letter N. The distance N is equal to the sum of the distance M and four hundred fifty thousandths of a millimeter (0.450 mm). The distance N equals 8.67 mm plus 0.450 mm. That is, the distance N equals nine and twelve hundredths millimeters (9.12 mm).

The radius of the scleral tissue fixation tool 3000 is seven hundred fifty microns (750μ). Seven hundred fifty microns is equivalent to seven hundred fifty thousandths of a millimeter (0.750 mm). The distance from the base plate 1730 of the surgical tool hand piece to the anterior edge of the drive blade 1140 is seven hundred fifty microns (750μ).

The position to place the center of the scleral tissue fixation tool 3000 is designated with the letter P in FIG. 50. In order to determine the position P subtract a distance of one and one half millimeters (1.5 mm) from the distance N. The distance P is the distance from the axis of eye 100 to the center of the scleral tissue fixation tool 3000. The distance P equals 9.12 mm minus 1.5 mm. That is, the distance P equals seven and sixty two hundredths millimeters (7.62 mm). As will be more fully described, an applanation marking plate may be used to mark the position of the center of the scleral tissue fixation tool 3000 on the sclera of eye 100. A micrometer is used to set the value of 7.62 mm on the applanation marking plate.

FIG. 51 illustrates an applanation marking plate assembly 5100. Applanation marking plate assembly 5100 comprises applanation marking plate 5110. Applanation marking plate 5110 is a transparent plate made of clear glass, plastic or other suitable material. In one advantageous embodiment, applanation marking plate 5110 comprises a square having sides that are approximately sixteen millimeters (16 mm) in length.

Applanation marking plate assembly 5100 further comprises a circular marking ring 5120 on applanation marking plate 5110. Marking ring 5120 has a circular shape with the center of the circle located in the center of applanation marking plate 5110. The size of marking ring 5120 is adjustable. Applanation marking plate assembly 5100 comprises a micrometer 5140 for adjusting the size of marking ring 5120.

Applanation marking plate assembly 5100 further comprises an applanating circle 5130 on applanation marking plate 5110. The center of applanating circle 5130 is located in the center of applanation marking plate 5110. The size of applanating circle 5130 is fixed. In one advantageous embodiment, the diameter of applanating circle 5130 is three millimeters (3.0 mm). The diameter of applanating circle 5130 may be greater than three millimeters (3.0 mm) or less than three millimeters (3.0 mm).

Applanation marking plate assembly 5100 may be used to mark the position for placing the scleral tissue fixation tool 3000 on the sclera of eye 100. First the surgeon uses micrometer 5140 to adjust the size of marking ring 5120 so that the radius of marking ring 5120 is equal to seven and sixty two hundredths millimeters (7.62 mm). Then the surgeon places the applanation marking plate 5110 on the center of the cornea of eye 100.

To determine the center of the cornea 104 of eye 100 the surgeon may use any of a number of prior art techniques. An exemplary prior art system for making corneal measurements is disclosed in U.S. Pat. No. 6,520,958 entitled “System and Methods for Imaging Corneal Profiles” issued Feb. 18, 2003.

To determine the center of the cornea 104 of eye 100 the surgeon may use a central fixation light source (not shown). The fixation light from the central fixation light source enters through one of the side ports of a surgical microscope (not shown). The fixation light then exits through an objective lens on the same side of the surgical microscope. Assume that the fixation light enters through the right side port and exits through the right objective lens of the surgical microscope.

The patient fixates the fixation light that comes through the right objective lens of the surgical microscope while the surgeon looks through only the right eyepiece of the surgical microscope. The surgeon then aligns the center of applanating circle 5030 with the patient's corneal Purkinje image of the fixation light to determine the location of the center of the cornea 104 of the patient.

The surgeon then applanates the cornea 104 of eye 100 to insure that the applanation of the cornea 104 of eye 100 is circular. The surgeon must make sure that the measurement is being made from the center of the cornea 104 and that the applanation is circular. The surgeon presses applanation plate 5110 down on the cornea 104 of eye 100 and marks a circle (on individual points) on the sclera 102 of eye 100 at the location of marking ring 5120. The marks on the sclera 102 of eye 100 define the position for locating the center of the scleral tissue fixation tool 3000. This location marks an optimum position for placing scleral pocket 120 to receive scleral prosthesis 200.

FIG. 52 illustrates a controller 5210 that is capable of carrying out the method of the present invention. Controller 5210 is coupled to and receives eye measurements from eye measurement equipment 5220. Eye measurement equipment 5220 may comprise, for example, an ultrasound biomicroscope for determining a value for the corneal diameter A, a keratometer for determining a value for the mean radius of curvature C of the cornea, and an ultrasound biomicroscope for determining a value of the axial length B of eye 100.

Controller 5210 is also coupled to an input unit 5230. Controller 5210 can receive input parameters and other information from the surgeon through input unit 5230, a memory, or other device or processor. For example, the surgeon can use input unit 5230 to inform controller 5210 of the age of the person whose eye is being measured.

Controller 5210 comprises a software processor 5240 that is capable of executing computer instructions stored in a memory (not shown) within controller 5210. Software processor 5240 comprises an operating system 5250 and an eye model application 5260. Eye model application 5260 comprises computer software instructions for making the various calculations of the method of the present invention.

Eye model application 5260 receives the values of the measured parameters of eye 100 that are measured by eye measurement equipment 5220. Eye model application 5260 uses the eye measurement values from eye measurement equipment 5220 and input from input unit 5230 to mathematically model the operation of eye 100 in accordance with the steps of the method of the present invention. Eye model application 5260 contains a database (not shown) that contains the empirically determined percentages (as a function of the age of eye 100) with which to multiply the thickness of lens 108 to determine the position of lens equatorial plane 130.

Eye model application 5260 obtains information about eye 100 from the mathematical model of eye 100 that is created by eye model application 5260. In particular, eye model application 5260 calculates a precise location for a scleral pocket 120 on the sclera 102 of eye 100. Information from eye model application 5260 may be output by controller 5210 to a data display 5270 for the surgeon to review.

Information from eye model application 5260 may also be supplied to surgical tool controller 1200 to assist the surgical tool controller in accurately positioning blade 1140 of surgical tool 1100. Surgical tool controller 1200 may use information from eye model application 5260 to automatically determine an incision point for the incision to create scleral pocket 120 while surgical tool 1100 is in place over the sclera 102 of eye 100. As previously mentioned, in one advantageous embodiment, scleral prosthesis 200 is capable of being filled with a fluid. Surgical tool controller 1200 may use information from eye model application 5260 to select a size of scleral prosthesis 200 when scleral prosthesis 200 is filled with fluid after scleral prosthesis 200 has been placed within scleral pocket 120.

Information from eye model application 5260 may also be supplied to applanation marking plate assembly 5100 to operate micrometer 5140 to accurately position marking ring 5120.

FIG. 53 illustrates a flow chart showing an advantageous embodiment of the method of the present invention. The steps of the method are collectively referred to with reference numeral 5300.

The values of the corneal diameter A, the corneal radius of curvature C, and the axial length B of eye 100 are measured (step 5310). The value of the radius D of the scleral shell 102 is then calculated from the measured values of A, B, and C. (step 5320). The thickness J of the lens is calculated and the position of the lens equatorial plane 130 is calculated (step 5330).

The distance L between the corneal plane 4950 and the lens equatorial plane 130 is then calculated (step 5340). The distance K from the center of the scleral shell 102 to the lens equatorial plane 130 is then calculated (step 5350). The distance M from the axis of eye 100 to the point where the lens equatorial plane 130 crosses the sclera 102 is then calculated (step 5360). The distance N from the center of cornea 104 to the front of the scleral pocket 120 is then calculated (step 5370). The method of present invention precisely determines the optimum position for the location of scleral pocket 120.

The invention having now been fully described, it should be understood that it may be embodied in other specific forms or variations without departing from its spirit or essential characteristics. Accordingly, the embodiments described above are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are intended to be embraced therein. 

What is claimed is:
 1. For use with a surgical tool, an apparatus comprising: a controller comprising a processing device, the controller operable to: (i) receive eye measurements that measure portions of an eye of a patient; (ii) use the eye measurements to create a mathematical model of the eye; (iii) determine from the mathematical model of the eye a location, within scleral tissue of the eye, of a scleral pocket that is to receive a scleral prosthesis; and (iv) output the determined location; wherein the controller is operable to determine the location of the scleral pocket by determining from the mathematical model a location of a lens equatorial plane of the eye and where a projection of the lens equatorial plane actually intersects a sclera of the eye; and wherein the controller is operable to determine the location of the lens equatorial plane by multiplying a thickness of a lens of the eye by an empirical percentage, the empirical percentage based on an age of the patient.
 2. The apparatus as claimed in claim 1, wherein the controller is operable to determine the location of the scleral pocket by: determining a radius of a scleral shell of the eye; determining a distance between a corneal plane of the eye and the lens equatorial plane; determining a distance from a center of the scleral shell to the lens equatorial plane based on the distance between the corneal plane and the lens equatorial plane; determining a distance from an axis of the eye to a location where the projection of the lens equatorial plane intersects the sclera based on the radius of the scleral shell and the distance from the center of the scleral shell to the lens equatorial plane; and determining a distance from the axis of the eye to one end of the scleral pocket based on the distance from the axis of the eye to the location where the projection of the lens equatorial plane intersects the sclera.
 3. The apparatus as claimed in claim 2, wherein the controller is operable to determine the radius of the scleral shell from a measured value of corneal diameter of a cornea of the eye, a measured value of mean radius of curvature of the cornea, and a measured value of an axial length of the eye.
 4. The apparatus as claimed in claim 1, wherein the controller is operable to determine the thickness of the lens by determining a difference between (i) a distance from an anterior central corneal surface of the eye and an anterior surface of the lens and (ii) a distance from the anterior central corneal surface and a posterior surface of the lens.
 5. The apparatus as claimed in claim 2, wherein the controller is operable to determine the distance between the corneal plane and the lens equatorial plane by subtracting (i) a distance between an anterior central corneal surface of the eye and the corneal plane from (ii) a distance between the anterior central corneal surface and the lens equatorial plane.
 6. The apparatus as claimed in claim 2, wherein the controller is operable to determine the distance from the center of the scleral shell to the lens equatorial plane by subtracting (i) the distance between the corneal plane and the lens equatorial plane from (ii) a distance between the center of the scleral shell and the corneal plane.
 7. The apparatus as claimed in claim 2, wherein the controller is operable to determine the distance from the axis of the eye to one end of the scleral pocket by adding (i) a specified distance and (ii) the distance from the axis of the eye to the location where the projection of the lens equatorial plane intersects the sclera.
 8. The apparatus as claimed in claim 2, wherein the controller is operable to determine the distance from the axis of the eye to one end of the scleral pocket by determining a position where it is optimal to locate a front of the scleral pocket on the sclera of the eye.
 9. The apparatus as claimed in claim 1, wherein the controller is further operable to determine from the mathematical model of the eye a distance from a center of a cornea of the eye to a position on the sclera of the eye where it is optimal to place a center of a scleral tissue fixation tool to restrain movement of the surgical tool when the surgical tool makes an incision in the sclera of the eye to form the scleral pocket.
 10. The apparatus as claimed in claim 1, wherein the controller is operable to receive information concerning the eye from an input unit.
 11. The apparatus as claimed in claim 1, wherein the controller is further operable to provide information derived from the mathematical model of the eye to one of: a data display, a surgical tool controller, and an applanation marking plate assembly.
 12. The apparatus of claim 1, wherein the controller is operable to determine the location of the scleral pocket within the scleral tissue of the eye such that the scleral prosthesis, once inserted into the scleral pocket, increases an effective working distance of a ciliary muscle in the eye to increases an amplitude of accommodation of the eye.
 13. For use with a surgical tool, a method comprising the steps of: receiving eye measurements that measure portions of an eye of a patient at a controller, the controller comprising a processing device; using the eye measurements at the controller to create a mathematical model of the eye; determining at the controller from the mathematical model of the eye a location, within scleral tissue of the eye, of a scleral pocket that is to receive a scleral prosthesis; and outputting the determined location; wherein determining the location of the scleral pocket comprises determining from the mathematical model a location of a lens equatorial plane of the eye and where a projection of the lens equatorial plane actually intersects a sclera of the eye; and wherein determining; the location of the lens equatorial plane comprises multiplying a thickness of a lens of the eye by an empirical percentage, the empirical percentage based on an age of the patient.
 14. The method as claimed in claim 13, wherein determining the location of the scleral pocket comprises: determining a radius of a scleral shell of the eye; determining a distance between a corneal plane of the eye and the lens equatorial plane; determining a distance from a center of the scleral shell to the lens equatorial plane based on the distance between the corneal plane and the lens equatorial plane; determining a distance from an axis of the eye to a location where the projection of the lens equatorial plane intersects the sclera based on the radius of the scleral shell and the distance from the center of the scleral shell to the lens equatorial plane; and determining a distance from the axis of the eye to one end of the scleral pocket based on the distance from the axis of the eye to the location where the projection of the lens equatorial plane intersects the sclera.
 15. The method as claimed in claim 13, further comprising the steps of: receiving at the controller, from an input unit, information concerning the eye; and providing information derived from the mathematical model of the eye to at least one of: a data display, a surgical tool controller, and an applanation marking plate assembly.
 16. The method of claim 14, wherein determining the radius of the scleral shell comprises determining the radius of the scleral shell using a measured value of corneal diameter of a cornea of the eye, a measured value of mean radius of curvature of the cornea, and a measured value of an axial length of the eye.
 17. The method of claim 14, wherein: determining the distance between the corneal plane and the lens equatorial plane comprises subtracting (i) a distance between an anterior central corneal surface of the eye and the corneal plane from (ii) a distance between the anterior central corneal surface and the lens equatorial plane; and determining the distance from the center of the scleral shell to the lens equatorial plane comprises subtracting (i) the distance between the corneal plane and the lens equatorial plane from (ii) a distance between the center of the scleral shell and the corneal plane.
 18. A system comprising: a memory configured to store a mathematical model of a patient's eye; and a processing device configured to: determine from the mathematical model of the eye a location, within scleral tissue of the eye, of a scleral pocket that is to receive a scleral prosthesis; and output the determined location; wherein the processing device is operable to determine the location of the scleral pocket by determining from the mathematical model a location of a lens equatorial plane of the eye and where a projection of the lens equatorial plane actually intersects a sclera of the eye; and wherein the processing device is operable to determine the location of the lens equatorial plane by multiplying a thickness of a lens of the eye by an empirical percentage, the empirical percentage based on an age of the patient.
 19. The system of claim 18, wherein the processing device is operable to determine the location of the scleral pocket by: determining a radius of a scleral shell of the eye; determining a distance between a corneal plane of the eye and the lens equatorial plane; determining a distance from a center of the scleral shell to the lens equatorial plane based on the distance between the corneal plane and the lens equatorial plane; determining a distance from an axis of the eye to a location where the projection of the lens equatorial plane intersects the sclera based on the radius of the scleral shell and the distance from the center of the scleral shell to the lens equatorial plane; and determining a distance from the axis of the eye to one end of the scleral pocket based on the distance from the axis of the eye to the location where the projection of the lens equatorial plane intersects the sclera.
 20. The system of claim 19, wherein: the processing device is operable to determine the radius of the scleral shell from a measured value of corneal diameter of a cornea of the eye, a measured value of mean radius of curvature of the cornea, and a measured value of an axial length of the eye; the processing device is operable to determine the thickness of the lens by determining a difference between (i) a distance from an anterior central corneal surface of the eye and an anterior surface of the lens and (ii) a distance from the anterior central corneal surface and a posterior surface of the lens; the processing device is operable to determine the distance between the corneal plane and the lens equatorial plane by subtracting (i) a distance between the anterior central corneal surface of the eye and the corneal plane from (ii) a distance between the anterior central corneal surface and the lens equatorial plane; the processing device is operable to determine the distance from the center of the scleral shell to the lens equatorial plane by subtracting (i) the distance between the corneal plane and the lens equatorial plane from (ii) a distance between the center of the scleral shell and the corneal plane; and the processing device is operable to determine the distance from the axis of the eye to one end of the scleral pocket by adding (i) a specified distance and (ii) the distance from the axis of the eye to the location where the projection of the lens equatorial plane intersects the sclera.
 21. A method comprising: storing a mathematical model of a patient's eye in a memory of a controller, the controller also comprising a processing device; determining at the controller from the mathematical model of the eye a location, within scleral tissue of the eye, of a scleral pocket that is to receive a scleral prosthesis; and outputting the determined location; wherein determining the location of the scleral pocket comprises determining from the mathematical model a location of a lens equatorial plane of the eye and where a projection of the lens equatorial plane actually intersects a sclera of the eye; and wherein determining the location of the lens equatorial plane comprises multiplying a thickness of a lens of the eye by an empirical percentage, the empirical percentage based on an age of the patient. 